Relevance and redundancy as selection techniques for human-autonomy sensor fusion

2017 IEEE International Conference on Multisensor Fusion and Integration for Intelligent Systems (MFI) Pub Date : 2017-11-16 DOI:10.1109/MFI.2017.8170409

Justin D. Brody, Anna M. R. Dixon, Daniel Donavanik, R. Robinson, W. Nothwang

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Abstract

Human-autonomy teaming using physiological sensors poses a novel sensor fusion problem due to the dynamic nature of the sensor models and the difficulty of modeling their temporal and inter-subject variability. Developing analytical models therefore requires defining objective criteria for selection and weighting of sensors under an appropriate fusion paradigm. We investigate a selection methodology grounded in two intuitions: 1) that maximizing the relevance between sensors and target classes will enhance overall performance within a given fusion scheme; and 2) that minimizing redundancy amongst the selected sensors will not harm fusion performance and may improve precision and recall. We apply these intuitions to a human-autonomy image classification task. Preliminary results indicate strong support for the relevance hypothesis and weaker effects for the redundancy hypothesis. This relationship and its application to human-autonomy sensor fusion are explored within a framework employing three common fusion methodologies: Naive Bayes fusion, Dempster-Shafer theory, and Dynamic Belief Fusion.

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相关度和冗余度作为人类自主传感器融合的选择技术

由于传感器模型的动态性以及对其时间和主体间可变性建模的困难，使用生理传感器的人类自主团队提出了一个新的传感器融合问题。因此，开发分析模型需要在适当的融合范式下定义选择和加权传感器的客观标准。我们研究了一种基于两个直觉的选择方法:1)在给定的融合方案中，最大化传感器和目标类别之间的相关性将提高整体性能;2)最小化所选传感器之间的冗余不会损害融合性能，并可能提高精度和召回率。我们将这些直觉应用于人类自主图像分类任务。初步结果表明相关性假设得到了较强的支持，冗余假设的影响较弱。这种关系及其在人类自主传感器融合中的应用在采用三种常见融合方法的框架内进行了探讨:朴素贝叶斯融合、Dempster-Shafer理论和动态信念融合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 IEEE International Conference on Multisensor Fusion and Integration for Intelligent Systems (MFI)

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